Fun with the Radio Shack EC-4026

Fun with the Radio Shack EC-4026 

(Equivalent of the Casio fx-4500P)

Programming Notes

 

The syntax for prompting for variables and displaying results are slightly different from the usual Casio programming language (as I mentioned, the EC-4026 is a clone of the fx-4500P).  Check out the unusual If-Then-Else-End structure as well. 

Prompting Syntax:

{var} : var “prompt string”

Example:

 {X}: X”ENTER X”

Display Syntax:

Calculation

“Display string” ◢  (solid right triangle, [2ndF] [↑])

Example: 

X

“F(X)=” ◢

The If-Then-Else-End Structure:

If condition ⇒ do if the condition is true ⇏do if condition is false ◺  (clear right triangle, [2ndF] [√])

Note:  I symbolize the [x^y] by ^.

Finding the Monthly Payment of a Mortgage with Total Interest Paid and Total Cash Outflow

Program MORTGAGE:

L1  Fix 2

L2 {A}: A”LOAN AMOUNT”

L3 {Y}: Y”YEARS”

L4 {I}: I”RATE”

L5 I = I/1200

L6 N = Y*12

L7 P = A*(I(1+I)^N)/((1+I)^N-1)

L8 “MONTHLY PMT” ◢

L9 N*P

L10 “OUTFLOW” ◢

L11 N*P-A

L12 “TOTAL INTEREST” ◢

L13 Norm

Example:

A:  Loan is $250,000.00

Y:  30 years

I: Interest rate of 4%

Results:

P:  Payment:  $1,193.59

Outflow:  $429,673.77

Total Interest:  $179,673.77

Midlength, Height, and Area of a Trapezoid

Program TRAPEZIOD:

L1 {A}

L2 {B}
L3 {C}

L4 {D}

L5 H = √((-A+B+C+D)*(A-B+C+D)*(A-B+C-D)*(A-B-C+D))/(2*Abs(B-A))

L6 M = (A+B)/2

L7 K = M*H

L8 M

L9 “MIDLENGTH” ◢

L10 H

L11 “HEIGHT” ◢

L12 K

L13 “AREA” ◢

Quadratic Equation A*x^2 + B*x + C = 0

Program QUAD:

L1 {A}: A”A”

L2 {B}: B”B”

L3 {C}: C”C”

L4 D = B^2-4*A*C

L5 D<0 ⇒ Goto 1 ◺

L6 X = (-B + √D)/(2A) ◢

L7 Y = (-B - √D)/(2A) ◢

L8 Goto 0

L9 Lbl 1

L10 X = -B/(2A)

L11 “REAL” ◢

L12 Y = √(Abs D)/(2A)

L13 “IMAG” ◢

L14 Lbl 0

L15 “DONE” ◢

Example:

3x^2 + 6x – 1 = 0; A = 3, B = 6, C = -1

Result:  0.154700538, -2.154700538

3x^2 + 6x + 10 = 0; A = 3, B = 6, C = 10

Result:  REAL: -1, IMAG: 1.527525232.  -1 ± 1.527525232i

Minimum Loss Matching

Variables:

Input: Y = Z0, Z = Z1

Output:

R = R1

S = R2

L = Loss Marching

Program MINLOSS:

L1 1:  “Z1<Z0” ◢

L2 {Y}: Y”Z0”

L3 {Z}: Z”Z1”

L4 L = √(1 – Z/Y)

L5 R = Y*L: “R1”◢

L6 S = Z/L: “R2” ◢

L7 L = 20 log (√(Y/Z) + √(Y/Z – 1)): “LOSS” ◢

Example:

Input:

Y: Z0: 15

Z: Z1: 10

Output:

R1: 8.66025 Ω

R2:  17.32051 Ω

Loss:  5.71948

Add Two Polar Numbers

Polar and Rectangular conversions

Variable	Rectangular Results	Polar Results
V	x	r
W	y	θ

Program ADDPOLAR:

L1 {R}: R”R1”

L2 {S}: S”ANG1”

L3 Rec(R,S)

L4 R = V: S = W

L5 {V}: V”R2”

L6 {W}: W”ANG2”

L7 Rec(V,W)

L8 R = R+V: S = S+W

L9 Pol(R,S)

L10 V: “R SUM”◢

L11 W: “ANG SUM”◢

Example:

4 ∠ 20° + 3 ∠ 11 ° (In Degrees Mode)

Result (rounded to 4 digits): 6.9789 ∠ 16.1442°

How to Handle a Tax Bracket (Simple Sample)

Take a sample (and simplified) tax bracket, where income is X:

0 < X ≤ 200:  tax rate is 10% of X

200 < X ≤ 600:  tax rate is 13% of X

600 < X: tax rate is 16% of X

Program:

L1 {X}: X”X”

L2 X > 600 ⇒ P = 16: Goto 1 ◺

L3 X > 200 ⇒ P = 13: Goto 1 ◺

L4 P = 10

L5 Lbl

L6 X * P/100

Eddie

All original content copyright, © 2011-2018.  Edward Shore.   Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited.  This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.  Please contact the author if you have questions.

Fun with the Radio Shack EC-4004

Fun with the Radio Shack EC-4004

Complex Number Multiplication

(a + bi) * (c + di) = (a*c – b*d) + (b*c + a*d)i

Store values in the following memory registers before running the program:

K1 = a

K2 = b

K3 = c

K4 = d

Output is stored in registers K5 (real part) and K6 (imaginary part).

Program:

Kout 1

*

Kout 3

-

Kout 2

*

Kout 4

=

Kin 5

HLT

Kout 2

*

Kout 3

+

Kout 1

*

Kout 4

=

Kin 6

Example:

(-8 + 3i)*(6 + 3i)   (K1 = -8, K2 = 3, K3 = 6, K4 = 3)

Result:  -57 – 6i (K5 = -57, K6 = -6)]

Product of Integers

The following program will between and b:  Product = a * (a + 1) * (a + 2) * … * b

P = Π n from n = a to b

Store values in the following memory registers before running the program:

K1 = a

M = b

K2 = 1 (store 1 in K2 each time)

Program:

Kout 1

Kin* 2

1

Kin+ 1

Kout 1

X ≤ M

Kout 2

Example:  Π n from n = 5 to 8:  P = 5 * 6 * 7 * 8

Store 5 in K1, 8 in M (Inv Min), 1 in K2. 

Heron’s Formula

The program calculates the area of the triangle.  Store the length of the sides in registers K1, K2, and K3.  The register K4 is used in the calculation and ultimately have the area.

K4 = (K1 + K2 + K3)/2

Area = √(K4 * (K4 – K1) * (K4 – K2) * (K4 – K3))

Program:

Kout 1

Min

Kout 2

M+

Kout 3

M+

MR

÷

2

=

Min

Kin 4

MR

-

Kout 1

=

Kin* 4

MR

-

Kout 2

=

Kin* 4

MR

-

Kout 3

=

Kin* 4

Kout 4

√

Kin 4

Example:

K1 = 16.4, K2 = 13.8, K3 = 11.4

Area = 77.60164947

Catenaries

The program calculates the length of the wire in a catenary (2*s). 

Input:

K1 = Horizontal Tension

K2 = Weight of the wire (lb-ft, N, etc)

K3 = half of the distance between the poles

Program:

Kout 1

÷

Kout 2

*

(

Kout 2

*

Kout 3

÷

Kout 1

)

sinh

=

*

2

=

Example:

Input:

K1 (H) = 40N

K2 (weight) = 0.227 N

K3 (half distance between poles) = 32.6 m

Result: 65.5726 m

Source:  Chris M. Alley and Brenda M. Cornitius TI-36 Solar Guidebook Texas Instruments. 1985.

Mass Dragged on the Table by a Pulley

The program solves the following systems:

T – M1*a = μ*M1*g

T + M2*a = M2*g

Input:

K1 = mass 1 in kg

K2 = mass 2 in kg

K3 = friction of the table factor (μ)

Output:

K4 = acceleration (a) m/s^2

K5 = tension of the rope (N)

Tension is displayed first, then acceleration

SI units are assumed, where g = 9.80665 m/s^2 (Earth’s gravity constant)

Program:

9

.

8

0

6

6

5

Kin 4

*

(

Kout 2

Kin 5

-

Kout 1

Kin+ 5

*

Kout 3

)

=

÷

Kout 5

=

Kin 5

HLT

Kin- 4

Example:

K1 = 4.3 kg (mass 1)

K2 = 6.4 kg (mass 2)

K3 = 0.1 (friction μ)

Results:

T = 27.7445 N (tension, K5)

a = 5.47156 m/s^2 (acceleration, K4)

Eddie

All original content copyright, © 2011-2018.  Edward Shore.   Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited.  This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.  Please contact the author if you have questions.

Retro Review: Casio fx-450 Calculator

Retro Review:  Casio fx-450 Calculator

General Information

Company:  Casio

Type:  Solar Scientific Algebraic (postfix)

Memory:  1 (store, recall, M+)

Years:  1983 (probably produced during the 1980s with various editions)

Original Cost: Unknown, my guess is $20-$30

Casio Ledudu’s page on fx-450:  http://casio.ledudu.com/pockets.asp?type=1334&lg=eng

It’s a Folding Calculator!

The Casio fx-450 is a folding scientific calculator: one side has the normal, plastic keys with the display and solar panel.  The scientific functions are located on the other panel are touch, rubber-like keys.  The large amount of keys allows for a relatively uncrowded keyboard since the shift key only affects a few keys. 

Modes included on fx-450:

* Single Variable Statistics

* Base Conversions with Boolean conversions (BIN, OCT, HEX)

In addition, the fx-450 has fraction calculations and nine scientific constants (by pressing [MODE] [SHIFT] [1-9]).  The constants, with the exception of the speed of light, have older values (they were updated as of the 2014 CODATA) and they are:

1. Speed of Light (c)

2. Plank’s constant (h)

3. Universal gravitational constant (G)

4. Electron charge (e)

5. Mass of an electron (me)

6. Atomic mass constant (u)

7. Avogadro’s constant (Na)

8. Boltzmann constant (k)

9. Molar volume of ideal gas (Vm)

Verdict

I like the idea of a folding keyboard, especially one of this design.  However, I recommend that you take extra care of the calculator. If the calculator was shipped in bubble wrap, I would keep the bubble wrap and store the calculator.  A concern is the contacts to the scientific keys could be worn. 

The fx-450 is a multi-function scientific calculator with a great set of features and it makes a good collector’s item. 

Eddie

All original content copyright, © 2011-2018.  Edward Shore.   Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited.  This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.  Please contact the author if you have questions.

Fun with the HP 15C

Fun with the HP 15C

Happy Independence Day, United States!

Fractional Derivative:  kth Derivative of f(x) = x^n

This program calculates the kth derivative of x^n. The program allows for partial derivatives of x^n (where k is not an integer, such as half-integers).

Formula:

d^k/dx^k x^n = n!/(n-k)! * x^(n-k)

Input:

R0: point (x’)

R1:  n

R2: k

Program:

Step	Key	Code
001	LBL A	42, 21, 11
002	RCL 0	45, 0
003	RCL 1	45, 1
004	RCL - 2	45, 30, 2
005	y^x	14
006	LAST x	43, 36
007	x!	42, 0
008	1/x	15
009	*	20
010	RCL 1	45, 1
011	x!	42, 0
012	*	20
013	RTN	43, 32

Example:

d/dx^4 x^8  at x = 6

R0 = x’ = 6

R1 = n = 8

R2 = k = 4

Result:  2177280

d/dx^1.5 x^3.4 at x = 1

R0 = x’ = 1

R1 = n = 3.4

R2 = k = 1.5

Result:  5.5469

Sight Reduction Table

The program calculates altitude and azimuth of a given celestial body.

Inputs:

R1: Local Hour Angle (LHA), west is positive, east is negative

R2: The observer’s latitude on Earth, north is positive, south is negative (L)

R3: Declination of the celestial’s body, north is positive, south is negative (δ)

Each entry will need to be in decimal format.  If your angels are in HMS (hours-minutes-seconds) format, convert the angels to decimals by →H before storing the values.

Formulas:

Altitude: 

H = asin (sin δ sin L + cos δ cos L cos LHA)

Azimuth:

Z = acos ((sin δ – sin L sin H) ÷ (cos H cos L))

If sin LHA < 0 then Z = 360° - Z

Outputs:

Altitude (in decimal), R/S, Azimuth (in decimal)

Program:

Step	Key	Code
001	LBL C	42, 21, 13
002	DEG	43, 7
003	RCL 3	45, 3
004	SIN	23
005	RCL 2	45, 2
006	SIN	23
007	*	20
008	RCL 3	45, 3
009	COS	24
010	RCL 2	45, 2
011	COS	24
012	*	20
013	RCL 1	45, 1
014	COS	24
015	*	20
016	+	40
017	ASIN	43, 23
018	STO 4	44, 4
019	R/S	31
020	SIN	23
021	RCL 2	45, 2
022	SIN	23
023	*	20
024	CHS	16
025	RCL 3	45, 3
026	SIN	23
027	+	40
028	RCL 4	45, 4
029	COS	24
030	RCL 2	45, 2
031	COS	24
032	*	20
033	÷	10
034	ACOS	43, 24
035	STO 5	44, 5
036	RCL 1	45, 1
037	SIN	23
038	TEST 2 (x<0)	43, 30, 2
039	GTO 1	22, 1
040	3	3
041	6	6
042	0	0
043	RCL - 5	45, 30, 5
044	STO 5	44, 5
045	LBL 1	42, 21, 1
046	RCL 5	45, 5
047	RTN	43, 32

Source:  “NAV 1-19A Sight Reduction Table”    HP 65 Navigation Pac.  Hewlett Packard, 1974.

Three Point Lagrangian Interpolation

This program calculates a point (x0, y0) given three known points (x1, y1), (x2, y2), and (x3, y3) where x0 is in between min(x1, x2, x3) and max(x1, x2, x3).  Ideally, x1 < x2 < x3.

Input:

R0 = x0 (on the x stack)

Store before running the program:

R1 = x1, R4 = y1

R2 = x2, R5 = y2

R3 = x3, R6 = y3

Other registers used: R7, R8, R9

Step	Key	Code
001	LBL E	42, 21, 15
002	STO 0	44, 0
003	RCL 4	45, 4
004	STO 7	44, 7
005	RCL 5	45, 5
006	STO 8	44, 8
007	RCL 6	45, 6
008	STO 9	44, 9
009	RCL 0	45, 0
010	RCL - 1	45, 30, 1
011	STO * 8	44, 20, 8
012	STO * 9	44, 20, 9
013	RCL 0	45, 0
014	RCL – 2	45, 30, 2
015	STO * 7	44, 20, 7
016	STO * 9	44, 20, 9
017	RCL 0	45, 0
018	RCL – 3	45, 30, 3
019	STO * 7	44, 20, 7
020	STO * 8	44, 20, 8
021	RCL 1	45, 1
022	RCL – 2	45, 30, 2
023	STO ÷ 7	44, 10, 7
024	CHS	16
025	STO ÷ 8	44, 10, 8
026	RCL 1	45, 1
027	RCL – 3	45, 30, 3
028	STO ÷ 7	44, 10, 7
029	STO ÷ 9	44, 10, 9
030	RCL 2	45, 2
031	RCL – 3	45, 30, 3
032	STO ÷ 8	44, 10, 8
033	STO ÷ 9	44, 10, 9
034	RCL 7	45, 7
035	RCL + 8	45, 40, 8
036	RCL + 9	45, 40, 9
037	RTN	43, 32

Example:

R1 = 5, R4 = 0.4

R2 = 10, R5 = 0.9

R3 = 15, R6 = 1.3

R0 = 12, result: 1.0720

R0 = 8, result: 0.7120

Source:  R. Woodhouse.  “Lagrangian Interpolation Routines” Datafile Summer 1984 Vol. 3 No. 3, Page 14

Quadratic Equation with Complex Coefficients

This program solves the equation where B and C are complex numbers:

x^2 + B*x + C = 0

where the roots are:

x = -B/2 ± √(B^2/4 – C)

Store the following values before running:

R1 = real(B),  R2 = imag(B)

R3 = real(C), R4 = imag(C)

Output:

Root 1 (press [ f ], hold (i) for the complex part), R/S, Root 2

Program:

Step	Key	Code
001	LBL C	42, 21, 13
002	GSB 1	32, 1
003	GSB 2	32, 2
004	+	40
005	R/S	31
006	GSB 1	32, 1
007	GSB 2	32, 2
008	-	30
009	RTN	43, 32
010	LBL 1	42, 21, 1
011	RCL 1	45, 1
012	RCL 2	45, 2
013	I	42, 25
014	2	2
015	CHS	16
016	÷	10
017	RTN	43, 32
018	LBL 2	42, 21, 2
019	RCL 1	45, 1
020	RCL 2	45, 2
021	I	42, 25
022	x^2	43, 11
023	4	4
024	÷	10
025	RCL 3	45, 3
026	RCL 4	45, 4
027	I	42, 25
028	-	30
029	√	11
030	RTN	43, 32

Example:

x^2 + (-1 + i)*x + (3i) = 0

R1 = -1, R2 = 1

R3 = 0, R4 = 3

Results:

1.8229 – 1.8229i

-0.8229 + 0.8229i

x^2 + 3*x + (-5 + 6i) = 0

R1 = 3, R2 = 0

R3 = -5, R4 = 6

Results:

1.3862 – 1.0394i

-4.3862 + 1.0394i

Eddie

All original content copyright, © 2011-2018.  Edward Shore.   Unauthorized use and/or unauthorized distribution for commercial purposes without express and written permission from the author is strictly prohibited.  This blog entry may be distributed for noncommercial purposes, provided that full credit is given to the author.  Please contact the author if you have questions.